Gene Delivery Research Articles

Self-Assembled DNA-Collagen Bioactive Scaffolds Promote Cellular Uptake and Neuronal Differentiation.

Different modalities of DNA/collagen complexes have been utilized primarily for gene delivery studies. However, very few studies have investigated the potential of these complexes as bioactive scaffolds. Further, no studies have characterized the DNA/collagen complex formed from the interaction of the self-assembled DNA macrostructure and collagen. Toward this investigation, we report herein the fabrication of novel bioactive scaffolds formed from the interaction of sequence-specific, self-assembled DNA macrostructure and collagen type I. Varying molar ratios of DNA and collagen resulted in highly intertwined fibrous scaffolds with different fibrillar thicknesses. The formed scaffolds were biocompatible and presented as a soft matrix for cell growth and proliferation. Cells cultured on DNA/collagen scaffolds promoted the enhanced cellular uptake of transferrin, and the potential of DNA/collagen scaffolds to induce neuronal cell differentiation was further investigated. The DNA/collagen scaffolds promoted neuronal differentiation of precursor cells with extensive neurite growth in comparison to the control groups. These novel, self-assembled DNA/collagen scaffolds could serve as a platform for the development of various bioactive scaffolds with potential applications in neuroscience, drug delivery, tissue engineering, and in vitro cell culture.

TRPML-1 Dysfunction and Renal Tubulopathy in Mucolipidosis Type IV.

Loss of function mutations in the lysosomal channel TRPML-1 cause mucolipidosis type IV (MLIV), a rare lysosomal storage disease characterized by neurological defects, progressive vision loss, and achlorhydria. Recent reports have highlighted kidney disease and kidney failure in patients with MLIV during the second to third decade of life; however, the molecular mechanisms driving kidney dysfunction remain poorly understood. A cross-sectional review of medical records from 21 MLIV patients (ages 3-43 years) was conducted to assess kidney function impairment. Additionally, we examined the kidney phenotype of MLIV mice at various ages, along with human kidney cells silenced for TRPML-1 and primary tubular cells from wild-type and MLIV mice. Immunohistology and cell biology approaches were used to phenotype nephron structure, the endolysosomal compartment, and inflammation. Kidney function was assessed through proteomic analysis of mouse urine and in vivo renal filtration measurements. Of the 21 MLIV patients only adults were diagnosed with stage 2-3 chronic kidney disease. Laboratory abnormalities included decreased eGFR, higher levels BUN/Creatine in bloodand proteinuria. In MLIV mice, we observed significant alterations in endolysosomal morphology, function, and impaired autophagy in proximal and distal tubules. This led to the accumulation of megalin (LRP2) in the subapical region of proximal tubular cells, indicating a block in apical receptor-mediated endocytosis. In vivo and in vitro experiments confirmed reduced fluid-phase endocytosis and impaired uptake of ligands, including β-lactoglobulin, transferrin, and albumin in MLIV proximal tubular cells. Urine analysis revealed tubular proteinuria and enzymuria in mice with MLIV. Additionally, early-stage disease was marked by increased inflammatory markers, fibrosis, and activation of the pro-inflammatory transcription factor NF-κB, coinciding with endolysosomal defects. Importantly, AAV-mediated TRPML-1 gene delivery reversed key pathological phenotypes in Mucolipidosis type IV mice, underscoring TRPML-1's critical role in kidney function. Our findings link TRPML-1 dysfunction to the development of kidney disease in MLIV, providing new insights into its pathogenesis and potential therapeutic targets.

Nanoparticle-Mediated Gene Delivery for Bone Tissue Engineering.

Critical-sized bone defects represent an urgent clinical problem, necessitating innovative treatment approaches. Gene-activated grafts for bone tissue engineering have emerged as a promising solution. However, traditional gene delivery methods are constrained by limited osteogenic efficacy and safety concerns. Recently, organic and inorganic nanoparticle (NP)vectors have attracted significant attention in bone tissue engineering for their safe, stable, and controllable gene delivery. Targeted gene delivery guided by insights into bone healing mechanisms, coupled with the multifunctional design of NPs, is crucial for enhancing therapeutic outcomes. Here, the theoretical foundations underlying NP-mediated gene therapy for enhancing bone healing across different histological stages are elucidated. Furthermore, the distinct attributes of functionalized NP vectors are discussed, and cutting-edge strategies aimed at optimizing gene delivery efficiency throughout the therapeutic process are highlighted. Additionally, the review addresses the unresolved challenges and prospects of this technology. This review may contribute to the continued development and clinical application of NP-mediated gene delivery for treating critical-sized bone defects.

The Langmuir Monolayer as a Model Membrane System for Studying the Interactions of Poly(Butyl Cyanoacrylate) Nanoparticles with Phospholipids at the Air/Water Interface

Poly(butyl cyanoacrylate) (PBCA) nanoparticles have numerous applications, including drug and gene delivery, molecular imaging, and cancer therapy. To uncover the molecular mechanisms underlying their interactions with cell membranes, we utilized a Langmuir monolayer as a model membrane system. This approach enabled us to investigate the processes of penetration and reorganization of PBCA nanoparticles when deposited in a phospholipid monolayer subphase. Atomic force microscopy (AFM) was employed to visualize Langmuir–Blodgett (LB) films of these nanoparticles. Additionally, we examined the state of a monolayer of Pluronic F68, a stabilizer of PBCA nanoparticles in suspension, by measuring the changes in relative surface area and surface potential over time in the barostatic regime following PBCA suspension spreading. Based on these findings, we propose a molecular mechanism for nanoparticle reorganization at the air–water interface.

Recent and Advanced Trends in Cancer Treatments

Background: Cancer treatment remains a critical area of clinical research, with numerous approaches developed depending on tumor type and stage. Recent advances in genetic and immunotherapy, bioinformatics, and genetic science have revolutionized cancer diagnosis and treatment. Emerging technologies such as gene delivery, oncolytic virotherapy, suicide gene therapy, and CRISPR/Cas9 offer promising therapeutic avenues. Methods: This review provides a detailed analysis of the latest techniques of Gene therapy, artificial intelligence, Nanocarrier Delivery Systems, Immunotherapy, CAR T-Cell Therapy, Epigenetics, Vaccines, and Clinical translation and assessing their therapeutic potential in cancer treatment. A review of early critical studies focused on the integration of immunotherapy, nanotechnology, and artificial intelligence (AI) in cancer therapies with emphasis on targeted delivery systems and precision medicine. Results: The review highlights the synergistic effects of combining targeted therapies with immunotherapy, particularly immune checkpoint inhibitors and CAR-T cell therapy. Therapies such as CRISPR/Cas9 demonstrate significant potential in cancer targeting, while advancements in nanocarrier delivery systems offer enhanced precision with reduced side effects. AI's role in improving cancer diagnosis and personalized treatment is also underscored. Conclusion: This comprehensive analysis of recent therapeutic approaches and technological advancements addresses gaps in previous reviews and offers updated insights into cutting-edge cancer treatments. The review emphasizes the evolving role of immunotherapy, nanotechnology, AI, and nanotechnology, providing clinicians and researchers with the most current and relevant information for optimizing cancer treatment strategies.

From Conventional to Cutting-edge: A Comprehensive Review on Drug Delivery Systems

: The essential need for efficacious conveyance of therapeutics to specific tissues or cells, refinement of drug formulations, and the scalability of industrial production drives the pre-sent-day demand for enhanced drug delivery systems (DDS). Newly devised drugs often exhibit suboptimal biopharmaceutical properties, resulting in diminished patient adherence and adverse side effects. The paramount importance of site-specific drug delivery lies in its capacity to facili-tate the targeted administration of diverse therapeutic agents, catering to both localized ailments and systemic treatments. Alongside targeted drug delivery strategies encompassing ligand-based targeting and stimuli-responsive systems, the advent of cutting-edge nanotechnologies such as nanoparticles, liposomes, and micelles has marked a paradigm shift. Additionally, personalized medicines have emerged as a consequential facet of drug delivery, emphasizing the customization of treatment approaches. Researchers have explored an excess of methodologies in the advance-ment of these formulation technologies, including stimuli-responsive drug delivery, 3D printing, gene delivery, and various other innovative approaches. This comprehensive review aims to pro-vide a holistic understanding of the past, present, and future of drug delivery systems, offering in-sights into the transformative potential of emerging technologies.

Polymeric Vehicles for Nucleic Acid Delivery: Enhancing the Therapeutic Efficacy and Cellular Uptake.

Therapeutic gene delivery may be facilitated by the use of polymeric carriers. When combined with nucleic acids to form nanoparticles or polyplexes, a variety of polymers may shield the cargo from in vivo breakdown and clearance while also making it easier for it to enter intracellular compartments. Polymer synthesis design choices result in a wide variety of compounds and vehicle compositions. Depending on the application, these characteristics may be changed to provide enhanced endosomal escape, longer-lasting distribution, or stronger connection with nucleic acid cargo and cells. Here, we outline current methods for delivering genes in preclinical and clinical settings using polymers. Significant therapeutic outcomes have previously been attained using genetic material- delivering polymer vehicles in both in-vitro and animal models. When combined with nucleic acids to form nanoparticles or polyplexes, a variety of polymers may shield the cargo from in vivo breakdown and clearance while also making it easier for it to enter intracellular compartments. Many innovative diagnoses for nucleic acids have been investigated and put through clinical assessment in the past 20 years. Polymer-based carriers have additional delivery issues due to their changes in method and place of biological action, as well as variances in biophysical characteristics. We cover recent custom polymeric carrier architectures that were tuned for nucleic acid payloads such genomemodifying nucleic acids, siRNA, microRNA, and plasmid DNA. In conclusion, the development of polymeric carriers for gene delivery holds promise for therapeutic applications. Through careful design and optimization, these carriers can overcome various challenges associated with nucleic acid delivery, offering new avenues for treating a wide range of diseases.

Marine Polysaccharides for Gene Delivery: Approaches and Prospective

: Polysaccharides from marine sources have been increasingly used in recent research due to their availability, affordability, biocompatibility, and biodegradability. These features make them promising candidates for use in nanotechnology in a wide variety of drug delivery systems, including those for gene therapy, tissue engineering, cancer therapy, wound dressing, biosensors, and water purification. Marine polysaccharides are of particular interest due to their distinct physicochemical and biological properties like chitin, alginate, carrageenan, fucoidan, and chitosan has inspired an array of nanostructures. This article summarizes the history, chemical composition, biological functions, and nanomedical uses of these marine polysaccharides. Marine polysaccharides are the topic of this review due to their potential utility in gene transfer.

Investigating Gene Delivery Efficiency of Poly(β‐amino ester) Derived From Poly(ethylene glycol) Diacrylate

AbstractPoly(β‐amino ester) (PβAE)‐based polymers hold promise for bacterial gene transfer due to their ability to form stable complexes with genetic material and facilitate efficient delivery into bacterial cells. These polymers are easily modified to improve uptake and protect DNA or RNA from degradation, providing a safer, more controlled alternative to traditional methods like chemical transformation or electroporation. In this study, we evaluated the gene transformation efficiency of cationic PβAE polymer, which was synthesized through an aza‐Michael addition reaction between piperazine and poly(ethylene glycol) diacrylate. Competent cells from E. coli strain DH5α were prepared with the optimized method using Ca2+ and Mg2+ ions. Different concentrations of the polymer were mixed with pRSET‐EmGFP before transforming into competent cells through the heat shock method. Transformed cells were checked on medium containing ampicillin, and by using colony PCR, transformation efficiency was calculated. Based on our findings, we observed a successful transformation of the EmGFP gene in case of having the polymer. Furthermore, the PβAE at high concentrations (20–100 ng µL−1) increased transformation efficiency more than twice as compared to the case of no polymer added. In conclusion, PβAE can effectively increase transformation efficiency.

The Emerging Treatment of BCG (Bacillus Calmette-Guérin)-Unresponsive Non–Muscle-Invasive Bladder Cancer

Bacillus Calmette-Guérin (BCG) remains the cornerstone in the treatment of high-risk non-muscle-invasive bladder cancer (NMIBC), effectively preventing recurrence and progression. Unfortunately, a significant proportion of patients are classified as BCG-unresponsive, and there have been no definite alternative treatments for these disease group except for radical cystectomy, which is still challenging and sometimes not applicable. Therefore, there has been a need for alternative bladder-preserving treatments for patients who desire a bladder-sparing approach or are too frail for major surgery. Intravesical therapies, such as gemcitabine, mitomycin C and docetaxel, are mostly studied approaches, showing some promising results. However, no definitive conclusion has be drawn because of the heterogeneity of the studies and protocols and the limited number of patients enrolled in most of these studies. Immunotherapy and anti-inflammatory agents, though promising, require further validation through ongoing clinical trials to ensure their safety and efficacy. Gene therapy is also being explored, though it is in its early stages, with challenges in gene delivery and immune regulation still to be addressed. Photodynamic therapy and hyperthermia, particularly in combination with other treatments like intravesical chemotherapy, have shown potential in improving outcomes for BCG-unresponsive patients, though they are not yet considered first-line treatments. While these novel approaches hold promise, more robust data and clinical trial results are necessary to guide treatment protocols. In conclusion, ongoing research and clinical trials will continue to shape the future of NMIBC management, with the aim of providing more effective and bladder-preserving options for patients.

Vector-Free Deep Tissue Targeting of DNA/RNA Therapeutics via Single Capacitive Discharge Conductivity-Clamped Gene Electrotransfer.

Viral vector and lipid nanoparticle based gene delivery have limitations around spatiotemporal control, transgene packaging size, and vector immune reactivity, compromising translation of nucleic acid (NA) therapeutics. In the emerging field of DNA and particularly RNA-based gene therapies, vector-free delivery platforms are identified as a key unmet need. Here, this work addresses these challenges through gene electrotransfer (GET) of "naked" polyanionic DNA/mRNA using a single needle form-factor which supports "electro-lens" based compression of the local electric field, and local control of tissue conductivity, enabling single capacitive discharge minimal charge gene delivery. Proof-of-concept studies for "single capacitive discharge conductivity-clamped gene electrotransfer" (SCD-CC-GET) deep tissue delivery of naked DNA and mRNA in the mouse hindlimb skeletal muscle achieve stable (>18 month) expression of luciferase reporter synthetic DNA, and mRNA encoding the reporter yield rapid onset (<3 h) high transient expression for several weeks. Delivery of DNAs encoding secreted alkaline phosphatase and Cal/09 influenza virus hemagglutinin antigen generate high systemic circulating recombinant protein levels and antibody titres. The findings support adoption of SCD-CC-GET for vaccines and immunotherapies, and extend the utility of this technology to meet the demand for efficient vector-free, precision, deep tissue delivery of NA therapeutics.

Identification of SLC35A1 as an essential host factor for the transduction of multi-serotype recombinant adeno-associated virus (AAV) vectors.

We conducted a genome-wide CRISPR/Cas9 screen in suspension 293 F cells transduced with rAAV5. The highly selected genes revealed after two rounds of screening included the previously reported KIAA0319L, TM9SF2, and RNF121, along with a cluster of genes involved in glycan biogenesis, Golgi apparatus localization, and endoplasmic reticulum penetration. In this report, we focused on solute carrier family 35 member A1 (SLC35A1), a Golgi apparatus-localized cytidine 5'-monophosphate-sialic acid (CMP-SIA) transporter. We confirmed that SLC35A1 knockout (KO) significantly decreased rAAV5 transduction to a level lower than that observed in KIAA0319L or TM9SF2 KO cells. Although SLC35A1 KO drastically reduced the expression of α2,6-linked SIA on the cell surface, the expression of α2,3-linked SIA, as well as the cell binding and internalization of rAAV5, was only moderately affected. Moreover, SLC35A1 KO significantly diminished the transduction of AAV multi-serotypes, including rAAV2 and rAAV3, which do not utilize SIAs for primary attachment. Notably, the SLC35A1 KO markedly increased transduction of rAAV9 and rAAV11, which primarily attach to cells via binding to galactose. Further analyses revealed that SLC35A1 KO significantly decreased vector nuclear import. More importantly, although the C-terminal cytoplasmic tail deletion (∆C Tail) mutant of SLC35A1 did not drastically decrease SIA expression, it significantly decreased rAAV transduction, as well as vector nuclear import, suggesting that the C-tail is critical in these processes. Furthermore, the T128A mutant significantly decreased SIA expression but still supported rAAV transduction and nuclear import. These findings highlight the involvement of the CMP-SIA transporter in the intracellular trafficking of rAAV vectors post-internalization.IMPORTANCErAAV is an essential tool for gene delivery in the treatment of genetic disorders; however, the mechanisms of rAAV transduction remain partially understood. GPR108 is vital for the transduction of most rAAV vectors, but not for rAAV5. We aimed to identify host factors that impact AAV5 transduction akin to GPR108. Using a genome-wide CRISPR/Cas9 screen in 293 F cells, we identified SLC35A1, a Golgi apparatus-localized CMP-sialic acid transporter that transports CMP-sialic acid from the cytoplasm into the Golgi apparatus for sialylation, is essential to rAAV transduction. Further studies across various AAV serotypes showed SLC35A1 significantly affects vector nuclear import post-internalization. These results underscore the crucial role of SLC35A1 in intracellular trafficking beyond the initial cell attachment of rAAV.

Penetratin and Mannose-Functionalized Cannabidiol Lipid Nanoparticles Encapsulating the BDNF Gene Reduce Amyloid-Induced Inflammation.

Inflammation is emerging as a critical player in the disease progression of Alzheimer's disease (AD) by its interaction with amyloid beta plaques in a feed-forward loop. There is also a decline in the nourishment and enriching neurotrophic factor, brain-derived neurotrophic factor (BDNF), in the brain. Therefore, supplementing the brain with BDNF by gene delivery and delivering the anti-inflammatory agent, cannabidiol (CBD) in this case, to mitigate inflammation-induced disease cascade offers an attractive treatment strategy. To achieve the brain localization of CBD and pBDNF, lipid nanoparticles (LNPs) functionalized with mannose and penetratin were utilized. CBD and pBDNF were successfully encapsulated in the LNPs (more than 80%) with a size less than 180 nm, polydispersity index less than 0.25, and zeta potential of 23 mV. CBD was released from the formulation over a period of a week. The dual-functionalized LNPs demonstrated higher cellular uptake of CBD and expressed a significantly higher amount of BDNF (p-value <0.05) after transfection than their nonmodified counterparts in four brain cell lines, i.e., brain endothelial cells (b.END3), immortalized microglia cells (IMGs), primary astrocytes, and primary neurons. Similarly, the permeation of CBD through the dual-modified LNPs across the in vitro coculture blood-brain barrier model was significantly higher (p-value <0.05) compared to free CBD or nonfunctionalized nanoparticles. The LNPs demonstrated anti-inflammatory activity against lipopolysaccharides and human amyloid beta1-42 oligomer induction as they reduced the protein and mRNA expression of pro-inflammatory cytokines TNF-α (p < 0.05) and IL-1β (p < 0.05) in IMG cells. In summary, the penetratin and mannose-functionalized LNPs encapsulating CBD and pBDNF could serve as a promising therapy in AD, requiring further validation in animal models.

Rabies virus-mimicking liposomes for targeted gene therapy in Alzheimer’s disease

RNA interference (RNAi) harbors significant potential for treating neurological disorders; nevertheless, limited efficacy has been discerned. The presence of barriers within the central nervous system, coupled with the inherent instability of nucleic acids within biological conditions, poses formidable challenges in advancing effective gene delivery strategies. In this study, we designed and prepared a virus-mimic non-viral gene vector, rabies virus glycoprotein (RVG29)-decorated liposome (f(Lipo)-RVG29), to deliver small interfering RNAs to the brain. Alzheimer’s disease (AD) was chosen as a model of neurodegenerative disease in this context, and b-site APP cleaving enzyme silencing siRNA (siBACE1) was used. The developed liposomal delivery system has a particle size of under 80 nm with a spherical shape, positive zeta potential, and the ability to protect siRNA against nucleases. In vitro studies demonstrate that functionalizing the cationic liposome by the RVG29 targeting ligand significantly enhances the effectiveness of gene delivery and silencing. Examination through ex vivo imaging illustrates an increased deposition of fluorescent-labeled f(Lipo)-RVG29 within brain tissue after 12 h post application. Additionally, the in vivo delivery of f(Lipo)-RVG29 carrying siRNA has substantially suppressed BACE1 expression at both mRNA and protein levels within the brain tissue. Our results suggest that the developed non-viral vector could be a promising gene carrier system combining the synergistic effect of virus-mimic RVG29 ligand with bioinspired liposome that imitates the natural lipid bilayers of cell membranes for brain-targeted RNAi therapeutics.

Endoplasmic reticulum stress-related deficits in calcium clearance promote neuronal dysfunction that is prevented by SERCA2 gene augmentation.

Disruption of calcium (Ca2+) homeostasis in neurons is a hallmark of neurodegenerative diseases. Here, we investigate the mechanisms leading to Ca2+ dysregulation and ask whether altered Ca2+ dynamics impinge on neuronal stress and circuit dysfunction. Using two-photon microscopy, we show that ocular hypertension, a major risk factor in glaucoma, and optic nerve crush injury disrupt the capacity of retinal neurons to clear cytosolic Ca2+ leading to impaired light-evoked responses. Gene- and protein expression analysis reveal the loss of the sarco-endoplasmic reticulum (ER) Ca2+-ATPase2 pump (SERCA2/ATP2A2) in injured retinal neurons from mice and patients with primary open-angle glaucoma. Pharmacological activation or neuron-specific gene delivery of SERCA2 is sufficient to rescue single-cell Ca2+ dynamics and promote robust survival of damaged neurons. Furthermore, SERCA2 gene supplementation reduces ER stress, reestablishes circuit balance, and restores visual behaviors. Our findings reveal that enhancing the Ca2+ clearance capacity of vulnerable neurons alleviates organelle stress and promotes neurorecovery.

Carbon nanostructure: Cutting-edge platforms for advanced genetic transport

Gene therapy represents a groundbreaking approach to treating genetic disorders, cancers, and infectious diseases by directly modifying or correcting the genetic material within a patient’s cells. Unlike conventional therapies, which primarily alleviate symptoms, gene therapy addresses the root cause of diseases at the molecular level, offering the potential for long-term or even permanent cures. However, the success of this method depends on the development of safe, efficient, and targeted delivery systems that can overcome multiple biological barriers. Among non-viral vectors, carbon nanostructures such as carbon nanotubes (CNTs), carbon quantum dots (CQDs), and nanodiamonds (NDs) have emerged as promising candidates due to their high surface area, biocompatibility, and ability to be easily functionalized. Despite these advantages, obstacles such as low gene delivery efficiency and potential toxicity still hinder their widespread clinical use. This article reviews recent progress in the development of carbon nanostructures for gene delivery and discusses ongoing challenges. Continued advancements in this field have the potential to reshape gene therapy, bringing it closer to clinical reality.

CD46 Is a Protein Receptor for Human Adenovirus Type 64

Certain species D human adenoviruses (HAdV-D19, -D37, and -D64) are causative agents of epidemic keratoconjunctivitis. HAdV-D37 has previously been shown to bind CD46 (membrane cofactor protein) and sialic acid as adhesion receptors. HAdV-D64 is genetically highly similar to HAdV-D37, with an identical fiber protein sequence, but differs substantially in its penton base and hexon proteins, two other major capsid components, due to genetic recombination. Here, we demonstrate that, like HAdV-D37, HAdV-D64 virions bind directly to CD46 and that CD46 and sialic acid also function as receptors for HAdV-D64 on multiple cell types. Expression of CD46 on CD46-negative cells conferred susceptibility to HAdV-D64 entry. Specifically blocking HAdV-D64 binding to CD46 on the host cell surface strongly inhibits viral entry and gene delivery into multiple cell lines that represent target tissues. We show that CD46 is expressed on human conjunctival epithelial cells and directly binds to the HAdV-D64 virion. Our results suggest that HAdV-D64 may be used to deliver genes to target conjunctival cells and that interrupting HAdV-D64 entry through its interaction with CD46 may prevent or lessen adenovirus-associated ocular disease.

Tropism of adeno-associated virus serotypes in mouse lungs via intratracheal instillation

BackgroundGene therapy holds great potential for treating various acquired and inherited pulmonary diseases. Adeno-associated viral (AAV) vectors have been thought to be primary candidates for gene delivery in patients with pulmonary diseases. However, the tropism of AAVs in the lungs remains largely unknown.ResultsHere, we investigate the tropism of twenty serotypes of AAVs by examining AAV-packed vector expression of the enhanced green fluorescent protein (eGFP) in mice. AAV1, AAV4, AAV5, AAV6, AAV6.2, AAV-PHP.B, and AAV-PHP.S exhibit high transduction rates in the airway epithelium. AAV1, AAV4, AAV5, AAV6, and AAV6.2 highly infect club cells. AAV1, AAV4, AAV5, AAV6, AAV6.2, and AAV-PHP.B efficiently infect ciliated cells. AAV8 and AAVrh10 can infect a few alveolar type I cells. AAV1, AAV5, AAV6, AAV6.2, AAV9, and AAVie can infect alveolar type II cells. AAV1, AAV5, AAVie, AAV-PHP.B, AAV-PHP.eB, and AAV-PHP.S can infect a few endothelial cells. However, none of these AAVs can efficiently infect neuroendocrine or smooth muscle cells.ConclusionsOur findings provide comprehensive information about the tropism of AAVs in pulmonary epithelium in mice, which might be helpful in developing efficient AAV-mediated gene therapy strategies for pulmonary disease treatment.

Non-Viral Systems Based on PAMAM-Calix-Dendrimers for Regulatory siRNA Delivery into Cancer Cells

Cancer is one of the most common diseases in developed countries. Recently, gene therapy has emerged as a promising approach to cancer treatment and has already entered clinical practice worldwide. RNA interference-based therapy is a promising method for cancer treatment. However, there are a number of limitations that require vectors to deliver therapeutic nucleic acids to target tissues and organs. Active research is currently underway to find highly effective, low-toxic nanomaterials capable of acting as nanocarriers. In this study, we demonstrated for the first time the ability of symmetrical polyamidoamine dendronized thiacalix[4]arenes (PAMAM-calix-dendrimers) to form stable positively charged complexes with siRNAs, protect them from enzymatic degradation, and efficiently deliver gene material to HeLa cells. A distinctive feature of PAMAM-calix-dendrimers was the unusual decrease in hemo- and cytotoxicity with increasing generation, while these compounds did not cause toxic effects at concentrations required for siRNA binding and delivery. A comparative analysis of the efficiency of complex formation of PAMAM-calix-dendrimers and classical PAMAM dendrimers with siRNAs was also performed. The findings may facilitate the creation of novel unique gene delivery systems for cancer nanomedicine development.

State of the art and perspectives of gene therapy in heart failure. A scientific statement of the Heart Failure Association of the ESC, the ESC Council on Cardiovascular Genomics and the ESC Working Group on Myocardial & Pericardial Diseases.

Gene therapy has recently become a reality in the treatment of cardiovascular diseases. Strategies to modulate gene expression using antisense oligonucleotides or small interfering RNA are proving to be safe and effective in the clinic. Adeno-associated viral vector-based gene delivery and CRISPR-Cas9-based genome editing have emerged as efficient strategies for gene delivery and repair in humans. Overall, gene therapy holds the promise not only of expanding current treatment options, but also of intervening in previously untackled causal disease mechanisms with little side effects. This scientific statement provides a comprehensive overview of the various modalities of gene therapy used to treat heart failure and some of its risk factors, and their application in the clinical setting. It discusses specifically the possibilities of gene therapy for hereditary heart diseases and (non)-genetic heart failure. Furthermore, it addresses safety and clinical trial design issues and challenges for future regulatory strategies.